Finding and Disambiguating References to Entities on Web Pages

ABSTRACT

A system and method for disambiguating references to entities in a document. In one embodiment, an iterative process is used to disambiguate references to entities in documents. An initial model is used to identify documents referring to an entity based on features contained in those documents. The occurrence of various features in these documents is measured. From the number occurrences of features in these documents, a second model is constructed. The second model is used to identify documents referring to the entity based on features contained in the documents. The process can be repeated, iteratively identifying documents referring to the entity and improving subsequent models based on those identifications. Additional features of the entity can be extracted from documents identified as referring to the entity.

RELATED APPLICATIONS

This application is a continuation of U.S. patent application Ser. No. 11/551,657, entitled “Finding and Disambiguating References to Entities on Web Pages,” filed Oct. 20, 2006, which application is incorporated by reference herein in its entirety.

TECHNICAL FIELD

The disclosed embodiments relate generally to information stored in the memory of a computer system. More particularly, the disclosed embodiments relate to disambiguating references to entities in documents stored in the memory of a computer system.

BACKGROUND

Ambiguity poses a serious challenge to the organization of information. For example, collecting information related to a particular entity is complicated by the existence of other entities with the same name. Overloading of entity names is common, whether the entity is a person (“Michael Jackson”), a place (“Paris”), or even a concept (“garbage collection”).

It is frequently useful to know the specific entity to which a document is referring. For example, if the goal is to extract, organize, and summarize information about Michael Jackson (the singer), one will want to look only at documents about Michael Jackson (the singer), and not at documents other Michael Jacksons. The ambiguity of language, of names, and of other common properties makes determining which entity a document is referring to a difficult task. Therefore, what is needed is a method for disambiguating references to entities in a document.

SUMMARY

A system and method for disambiguating references to entities in a document stored in a memory of a data processing system. In one embodiment, an iterative process is used to disambiguate references to entities in documents. An initial model is used to identify documents referring to an entity based on features contained in those documents. The occurrence of various features in these documents is measured. From the number occurrences of features in these documents, a second model is constructed. The second model is used to identify documents referring to the entity based on features contained in the documents. The process can be repeated, iteratively identifying documents referring to the entity and improving subsequent models based on those identifications.

In one embodiment, additional features of the entity are extracted from documents identified as referring to the entity. These extracted features are tested to determine if it is likely that they are features frequently associated with the entity. If it is determined that the extracted features are features of the entity, they are used to identify documents referring to the entity and to construct subsequent models.

In one embodiment, the number of documents identified as referring to an entity is used to estimate the absolute and/or relative importance of the entity. The contribution to the importance of an entity given by a document can be weighted by the estimated likelihood that the document refers to the entity, a metric of the importance of the document itself, such as its PageRank, or both.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 shows a network, in accordance with an embodiment of the invention.

FIGS. 2( a)-2(d) are block diagrams illustrating a data structure for facts within a repository of FIG. 1 in accordance with embodiments of the invention.

FIG. 2( e) is a block diagram illustrating an alternate data structure for facts and objects in accordance with embodiments of the invention.

FIG. 3 illustrates a system for estimating the importance of an entity, according to one embodiment of the present invention.

FIG. 4 illustrates a method for disambiguating references to an entity, according to one embodiment of the present invention.

FIG. 5 illustrates several examples of features associated with an entity and features associated with various documents, according to one embodiment of the present invention.

DESCRIPTION OF EMBODIMENTS

Embodiments of the present invention are now described with reference to the figures where like reference numbers indicate identical or functionally similar elements.

FIG. 1 shows a system architecture 100 adapted to support one embodiment of the invention. FIG. 1 shows components used to add facts into, and retrieve facts from a repository 115. The system architecture 100 includes a network 104, through which any number of document hosts 102 communicate with a data processing system 106, along with any number of object requesters 152, 154.

Document hosts 102 store documents and provide access to documents. A document is comprised of any machine-readable data including any combination of text, graphics, multimedia content, etc. A document may be encoded in a markup language, such as Hypertext Markup Language (HTML), i.e., a web page, in a interpreted language (e.g., JavaScript) or in any other computer readable or executable format. A document can include one or more hyperlinks to other documents. A typical document will include one or more facts within its content. A document stored in a document host 102 may be located and/or identified by a Uniform Resource Locator (URL), or Web address, or any other appropriate form of identification and/or location. A document host 102 is implemented by a computer system, and typically includes a server adapted to communicate over the network 104 via networking protocols (e.g., TCP/IP), as well as application and presentation protocols (e.g., HTTP, HTML, SOAP, D-HTML, Java). The documents stored by a host 102 are typically held in a file directory, a database, or other data repository. A host 102 can be implemented in any computing device (e.g., from a PDA or personal computer, a workstation, mini-computer, or mainframe, to a cluster or grid of computers), as well as in any processor architecture or operating system.

FIG. 1 shows components used to manage facts in a fact repository 115. Data processing system 106 includes one or more importers 108, one or more janitors 110, a build engine 112, a service engine 114, and a fact repository 115 (also called simply a “repository”). Each of the foregoing are implemented, in one embodiment, as software modules (or programs) executed by processor 116. Importers 108 operate to process documents received from the document hosts, read the data content of documents, and extract facts (as operationally and programmatically defined within the data processing system 106) from such documents. The importers 108 also determine the subject or subjects with which the facts are associated, and extract such facts into individual items of data, for storage in the fact repository 115. In one embodiment, there are different types of importers 108 for different types of documents, for example, dependent on the format or document type.

Janitors 110 operate to process facts extracted by importer 108. This processing can include but is not limited to, data cleansing, object merging, and fact induction. In one embodiment, there are a number of different janitors 110 that perform different types of data management operations on the facts. For example, one janitor 110 may traverse some set of facts in the repository 115 to find duplicate facts (that is, facts that convey the same factual information) and merge them. Another janitor 110 may also normalize facts into standard formats. Another janitor 110 may also remove unwanted facts from repository 115, such as facts related to pornographic content. Other types of janitors 110 may be implemented, depending on the types of data management functions desired, such as translation, compression, spelling or grammar correction, and the like.

Various janitors 110 act on facts to normalize attribute names, and values and delete duplicate and near-duplicate facts so an object does not have redundant information. For example, we might find on one page that Britney Spears' birthday is “12/2/1981” while on another page that her date of birth is “Dec. 2, 1981.” Birthday and Date of Birth might both be rewritten as Birthdate by one janitor and then another janitor might notice that 12/2/1981 and Dec. 2, 1981 are different forms of the same date. It would choose the preferred form, remove the other fact and combine the source lists for the two facts. As a result when you look at the source pages for this fact, on some you'll find an exact match of the fact and on others text that is considered to be synonymous with the fact.

Build engine 112 builds and manages the repository 115. Service engine 114 is an interface for querying the repository 115. Service engine 114's main function is to process queries, score matching objects, and return them to the caller but it is also used by janitor 110.

Repository 115 stores factual information extracted from a plurality of documents that are located on document hosts 102. A document from which a particular fact may be extracted is a source document (or “source”) of that particular fact. In other words, a source of a fact includes that fact (or a synonymous fact) within its contents.

Repository 115 contains one or more facts. In one embodiment, each fact is associated with exactly one object. One implementation for this association includes in each fact an object ID that uniquely identifies the object of the association. In this manner, any number of facts may be associated with an individual object, by including the object ID for that object in the facts. In one embodiment, objects themselves are not physically stored in the repository 115, but rather are defined by the set or group of facts with the same associated object ID, as described below. Further details about facts in repository 115 are described below, in relation to FIGS. 2( a)-2(d).

It should be appreciated that in practice at least some of the components of the data processing system 106 will be distributed over multiple computers, communicating over a network. For example, repository 115 may be deployed over multiple servers. As another example, the janitors 110 may be located on any number of different computers. For convenience of explanation, however, the components of the data processing system 106 are discussed as though they were implemented on a single computer.

In another embodiment, some or all of document hosts 102 are located on data processing system 106 instead of being coupled to data processing system 106 by a network. For example, importer 108 may import facts from a database that is a part of or associated with data processing system 106.

FIG. 1 also includes components to access repository 115 on behalf of one or more object requesters 152, 154. Object requesters are applications or components that request objects from repository 115. Object requesters 152, 154 may be understood as clients of the system 106, and can be implemented in any computer device or architecture. As shown in FIG. 1, a first object requester 152 is located remotely from system 106, while a second object requester 154 is located in data processing system 106. For example, in a computer system hosting a blog, the blog may include a reference to an object whose facts are in repository 115. An object requester 152, such as a browser displaying the blog will access data processing system 106 so that the information of the facts associated with the object can be displayed as part of the blog web page. As a second example, janitor 110 or other entity considered to be part of data processing system 106 can function as object requester 154, requesting the facts of objects from repository 115.

FIG. 1 shows that data processing system 106 includes a memory 107 and one or more processors 116. Memory 107 includes importers 108, janitors 110, build engine 112, service engine 114, and requester 154, each of which are preferably implemented as instructions stored in memory 107 and executable by processor 116. Memory 107 also includes repository 115. Repository 115 can be stored in a memory of one or more computer systems or in a type of memory such as a disk. FIG. 1 also includes a computer readable medium 118 containing, for example, at least one of importers 108, janitors 110, build engine 112, service engine 114, requester 154, and at least some portions of repository 115. FIG. 1 also includes one or more input/output devices 120 that allow data to be input and output to and from data processing system 106. It will be understood that data processing system 106 preferably also includes standard software components such as operating systems and the like and further preferably includes standard hardware components not shown in the figure for clarity of example.

FIG. 2( a) shows an example format of a data structure for facts within repository 115, according to some embodiments of the invention. As described above, the repository 115 includes facts 204. Each fact 204 includes a unique identifier for that fact, such as a fact ID 210. Each fact 204 includes at least an attribute 212 and a value 214. For example, a fact associated with an object representing George Washington may include an attribute of “date of birth” and a value of “Feb. 22, 1732.” In one embodiment, all facts are stored as alphanumeric characters since they are extracted from web pages. In another embodiment, facts also can store binary data values. Other embodiments, however, may store fact values as mixed types, or in encoded formats.

As described above, each fact is associated with an object ID 209 that identifies the object that the fact describes. Thus, each fact that is associated with a same entity (such as George Washington), will have the same object ID 209. In one embodiment, objects are not stored as separate data entities in memory. In this embodiment, the facts associated with an object contain the same object ID, but no physical object exists. In another embodiment, objects are stored as data entities in memory, and include references (for example, pointers or IDs) to the facts associated with the object. The logical data structure of a fact can take various forms; in general, a fact is represented by a tuple that includes a fact ID, an attribute, a value, and an object ID. The storage implementation of a fact can be in any underlying physical data structure.

FIG. 2( b) shows an example of facts having respective fact IDs of 10, 20, and 30 in repository 115. Facts 10 and 20 are associated with an object identified by object ID “1.” Fact 10 has an attribute of “Name” and a value of “China.” Fact 20 has an attribute of “Category” and a value of “Country.” Thus, the object identified by object ID “1” has a name fact 205 with a value of “China” and a category fact 206 with a value of “Country.” Fact 30 208 has an attribute of “Property” and a value of “Bill Clinton was the 42nd President of the United States from 1993 to 2001.” Thus, the object identified by object ID “2” has a property fact with a fact ID of 30 and a value of “Bill Clinton was the 42nd President of the United States from 1993 to 2001.” In the illustrated embodiment, each fact has one attribute and one value. The number of facts associated with an object is not limited; thus while only two facts are shown for the “China” object, in practice there may be dozens, even hundreds of facts associated with a given object. Also, the value fields of a fact need not be limited in size or content. For example, a fact about the economy of “China” with an attribute of “Economy” would have a value including several paragraphs of text, numbers, perhaps even tables of figures. This content can be formatted, for example, in a markup language. For example, a fact having an attribute “original html” might have a value of the original html text taken from the source web page.

Also, while the illustration of FIG. 2( b) shows the explicit coding of object ID, fact ID, attribute, and value, in practice the content of the fact can be implicitly coded as well (e.g., the first field being the object ID, the second field being the fact ID, the third field being the attribute, and the fourth field being the value). Other fields include but are not limited to: the language used to state the fact (English, etc.), how important the fact is, the source of the fact, a confidence value for the fact, and so on.

FIG. 2( c) shows an example object reference table 210 that is used in some embodiments. Not all embodiments include an object reference table. The object reference table 210 functions to efficiently maintain the associations between object IDs and fact IDs. In the absence of an object reference table 210, it is also possible to find all facts for a given object ID by querying the repository to find all facts with a particular object ID. While FIGS. 2( b) and 2(c) illustrate the object reference table 210 with explicit coding of object and fact IDs, the table also may contain just the ID values themselves in column or pair-wise arrangements.

FIG. 2( d) shows an example of a data structure for facts within repository 115, according to some embodiments of the invention showing an extended format of facts. In this example, the fields include an object reference link 216 to another object. The object reference link 216 can be an object ID of another object in the repository 115, or a reference to the location (e.g., table row) for the object in the object reference table 210. The object reference link 216 allows facts to have as values other objects. For example, for an object “United States,” there may be a fact with the attribute of “president” and the value of “George W. Bush,” with “George W. Bush” being an object having its own facts in repository 115. In some embodiments, the value field 214 stores the name of the linked object and the link 216 stores the object identifier of the linked object. Thus, this “president” fact would include the value 214 of “George W. Bush”, and object reference link 216 that contains the object ID for the for “George W. Bush” object. In some other embodiments, facts 204 do not include a link field 216 because the value 214 of a fact 204 may store a link to another object.

Each fact 204 also may include one or more metrics 218. A metric provides an indication of some quality of the fact. In some embodiments, the metrics include a confidence level and an importance level. The confidence level indicates the likelihood that the fact is correct. The importance level indicates the relevance of the fact to the object, compared to other facts for the same object. The importance level may optionally be viewed as a measure of how vital a fact is to an understanding of the entity or concept represented by the object.

Each fact 204 includes a list of one or more sources 220 that include the fact and from which the fact was extracted. Each source may be identified by a Uniform Resource Locator (URL), or Web address, or any other appropriate form of identification and/or location, such as a unique document identifier.

The facts illustrated in FIG. 2( d) include an agent field 222 that identifies the importer 108 that extracted the fact. For example, the importer 108 may be a specialized importer that extracts facts from a specific source (e.g., the pages of a particular web site, or family of web sites) or type of source (e.g., web pages that present factual information in tabular form), or an importer 108 that extracts facts from free text in documents throughout the Web, and so forth.

Some embodiments include one or more specialized facts, such as a name fact 207 and a property fact 208. A name fact 207 is a fact that conveys a name for the entity or concept represented by the object ID. A name fact 207 includes an attribute 224 of “name” and a value, which is the name of the object. For example, for an object representing the country Spain, a name fact would have the value “Spain.” A name fact 207, being a special instance of a general fact 204, includes the same fields as any other fact 204; it has an attribute, a value, a fact ID, metrics, sources, etc. The attribute 224 of a name fact 207 indicates that the fact is a name fact, and the value is the actual name. The name may be a string of characters. An object ID may have one or more associated name facts, as many entities or concepts can have more than one name. For example, an object ID representing Spain may have associated name facts conveying the country's common name “Spain” and the official name “Kingdom of Spain.” As another example, an object ID representing the U.S. Patent and Trademark Office may have associated name facts conveying the agency's acronyms “PTO” and “USPTO” as well as the official name “United States Patent and Trademark Office.” If an object does have more than one associated name fact, one of the name facts may be designated as a primary name and other name facts may be designated as secondary names, either implicitly or explicitly.

A property fact 208 is a fact that conveys a statement about the entity or concept represented by the object ID. Property facts are generally used for summary information about an object. A property fact 208, being a special instance of a general fact 204, also includes the same parameters (such as attribute, value, fact ID, etc.) as other facts 204. The attribute field 226 of a property fact 208 indicates that the fact is a property fact (e.g., attribute is “property”) and the value is a string of text that conveys the statement of interest. For example, for the object ID representing Bill Clinton, the value of a property fact may be the text string “Bill Clinton was the 42nd President of the United States from 1993 to 2001.” Some object IDs may have one or more associated property facts while other objects may have no associated property facts. It should be appreciated that the data structures shown in FIGS. 2( a)-2(d) and described above are merely exemplary. The data structure of the repository 115 may take on other forms. Other fields may be included in facts and some of the fields described above may be omitted. Additionally, each object ID may have additional special facts aside from name facts and property facts, such as facts conveying a type or category (for example, person, place, movie, actor, organization, etc.) for categorizing the entity or concept represented by the object ID. In some embodiments, an object's name(s) and/or properties may be represented by special records that have a different format than the general facts records 204.

As described previously, a collection of facts is associated with an object ID of an object. An object may become a null or empty object when facts are disassociated from the object. A null object can arise in a number of different ways. One type of null object is an object that has had all of its facts (including name facts) removed, leaving no facts associated with its object ID. Another type of null object is an object that has all of its associated facts other than name facts removed, leaving only its name fact(s). Alternatively, the object may be a null object only if all of its associated name facts are removed. A null object represents an entity or concept for which the data processing system 106 has no factual information and, as far as the data processing system 106 is concerned, does not exist. In some embodiments, facts of a null object may be left in the repository 115, but have their object ID values cleared (or have their importance to a negative value). However, the facts of the null object are treated as if they were removed from the repository 115. In some other embodiments, facts of null objects are physically removed from repository 115.

FIG. 2( e) is a block diagram illustrating an alternate data structure 290 for facts and objects in accordance with embodiments of the invention. In this data structure, an object 290 contains an object ID 292 and references or points to facts 294. Each fact includes a fact ID 295, an attribute 297, and a value 299. In this embodiment, an object 290 actually exists in memory 107.

FIG. 3 illustrates a system for estimating the importance of an entity, according to one embodiment of the present invention. In one embodiment, the system is implemented in a janitor. The system estimates the importance of the entity based on the references to the entity in documents 302. Some of the documents 302 contain one or more references to the entity; other documents 302 do not contain any references to the entity. Some of the documents 302 contain ambiguous references. An ambiguous reference is a reference that may or may not refer to the entity. In the case of certain ambiguous references, whether or not the reference refers to the entity can be difficult to determine based on the document 302 alone. Further processing of the document 302 containing the ambiguous reference, along with other documents 302, can be used to estimate a probability that the ambiguous reference refers to the entity.

A document 302 can be, for example, a web page, a Word document, an Excel spreadsheet, a personal online document (such as a Google Spreadsheet), a record in a database, or an image, audio, or video file. These examples have been given for the purposes of illustration and are not limiting. Other examples of documents 302 will be apparent to one of skill in the art without departing from the scope of the present invention. Furthermore, the documents 302 need not be of the same type. For example, according to one embodiment of the present invention, one document 302 can be an a web page and another document 302 can be a video file. In one embodiment, one or more of the documents 302 are or have been retrieved over the internet.

Features 308 are associated with the entity to which it is desired to disambiguate references. A feature is any property that can be represented in or by a document 302. For example, if the entity is Bob Dylan, features of the entity Bob Dylan could include, for example, the text “Bob Dylan”, an image of Bob Dylan, an audio clip of a song by Bob Dylan, a sentence about Bob Dylan, and so on. Features can also include metadata, geographic information, URLs, and other types of data that can be associated with an entity and/or a document.

In one embodiment, various features of the entity are stored as facts 306 in a fact repository. In this example, the facts 306 have a common object ID indicating that the facts 306 contain features associated with a common entity.

A disambiguation engine 310 is configured to receive the documents 302 and the facts 306 and return a probability 312 that a particular document refers to the entity. A method for estimating a probability 312 that a particular document refers to the entity is described herein with reference to FIG. 4.

In one embodiment, the probability 312 is used to estimate the relative or absolute importance of the entity. The probability 312 is an input to importance weighting 316, which returns an estimate 318 of the importance of the entity. In one embodiment, the importance of an entity is calculated as the net number of references (or likely references) to that entity on the world wide web. In another embodiment, the importance of an entity is calculated based on the probability 312 that one or more of the documents 302 refer to the entity. In another embodiment, the importance of an entity is based on a property 314 of a document that refers to the entity. For example, the importance of an entity can be calculated based on the PageRank of any web pages determined to be likely to refer to the entity. In yet another embodiment, the importance of an entity is based on the probability 312 that a document 302A refers to the entity and the PageRank property 314 of the document 302A. A sum of contributions by the various documents 302 can be taken to determine the estimate 318 of the importance of the entity. For example, the importance (I) of an entity (E) could be based on:

$I_{E} = {\sum\limits_{A}^{{all}\_ {documents}}\; {{P_{E}(A)}*{R(A)}}}$

where A is a document, P_(E). (A) is the probability that document A refers to the entity E, R(A) is the PageRank (or other property) of document A, and all_documents is a set of available documents (such as available documents with a probability of referring to entity E above some threshold).

In one embodiment, the probability 312 that a document 302A refers to the entity can be used to assist with the creation of new facts 306. For example, the document 302A may contain a feature not currently stored as a fact 306. If it is likely that the document 302A refers to the entity, additional facts 306 can be extracted and stored with an object ID indicating that they are associated with the entity. In one embodiment, the additional facts 306 are extracted responsive to the probability 312. In another embodiment, information regarding the entity to which the document 302A likely refers is stored for use by an importer 108 for future extractions.

In one embodiment, if the probability 312 is above some threshold, the document 302A is associated with the entity. For example, a link to the document 302A can be stored as a fact with an object ID indicating that the fact is associated with the entity. Advantageously, a fact is available in the fact repository citing a document 302A that refers to the entity.

FIG. 4 illustrates a method for disambiguating references to an entity, according to one embodiment of the present invention. In one embodiment, the method is performed by the disambiguation engine 310. According to various embodiments, the method can be performed by any kind of computer system. For example, in one embodiment, the method described herein can be used to disambiguate references in mail messages using facts obtained from a directory server. As another example, the method can be used to disambiguate references in documents on a user's machine.

The disambiguation engine 310 identifies 402 documents referring to an entity using a first model. A model is a set of rules specifying at least one combination of features sufficient for identifying a document referring to a particular entity. For example, a model can specify the probability that a document refers to a particular entity given a set of features in the document. The first model is used to identify a first set of documents likely to refer to the entity.

The disambiguation engine 310 determines 404 a subsequent model based on the features of the documents that are identified 402 as referring to the entity. For example, analysis of the documents identified 402 as referring to the entity can provide insights into the characteristics of documents that refer to the entity. These insights can be codified into a subsequent model. Further discussion of methods for determining 404 a subsequent model is included below.

The disambiguation engine 310 identifies 406 documents referring to the entity using the determined 404 model. The determined 404 model is used to identify 406 a second set of documents likely to refer to the entity. In one embodiment, the disambiguation engine 310 returns to determining 404 a subsequent model based on the identified 406 documents. The disambiguation engine 310 iterates through the loop illustrated in the method, advantageously converging towards increasingly accurate models. After some number of iterations, the disambiguation engine 310 returns the probabilities that various documents refer to the entity. In one embodiment, the disambiguation engine 310 returns a list of documents with a probability of referring to the entity above some threshold. In another embodiment, the disambiguation engine 310 returns a list of entities to which is it likely a particular document refers. For example, the disambiguation engine 310 can return a list of entities organized by the likelihood that the document refers to those entities. An entity to which it is more likely that the document refers could be listed above an entity to which it is less likely that the document refers. Entities below some likelihood threshold could be omitted from the list.

Furthermore, the list can also include an unknown entity. If a document refers to an entity of which few or no features are known, an unknown entity may be the most likely entity to which the document refers. For example, suppose the disambiguation engine 310 is aware of two “Michael Jackson” entities, the singer and the Secretary of Homeland Security. Many documents will be about one of these two entities, but numerous other pages will be about Michael Jacksons unknown to the disambiguation engine 310. The entity to which these documents most likely refer may be an “unknown” entity.

The number of iterations through the loop illustrated in FIG. 4 can depend on a variety of factors. For example, the disambiguation engine 310 can iterate a predetermined number of times. As other examples, the disambiguation engine 310 can iterate until the model has converged on a stable condition, a predetermined resource budget has been consumed, the improvement provided by an iteration falls below some improvement threshold, an iteration does not introduces a number of new features that falls below some threshold, the Kullback-Leibler divergence between the probability distribution over entity assignments to documents in subsequent iterations falls below some threshold, and so on. Other examples of methods for determining the number of times the disambiguation engine 310 should iterate will be apparent to one of ordinary skill in the art without departing from the scope of the present invention.

In one embodiment, the disambiguation engine 310 further adds/removes 408 features associated with the entity. For example, based on the documents identified 406 as referring to the entity, features associated with the entity can be removed, or new features can be associated with the entity. In one embodiment, added 408 features are used provisionally in a determine 404/identify 406 iteration. If the added 408 features behave in the model as other features of the entity, the features can be included as regular features. In one embodiment, added 408 features can be stored as facts in a fact repository.

In one embodiment, the first model indicates that a document contains a reference to the entity if the name of the entity and one other feature occurs in the document. The first model can also include further requirements, such as a requirement that the name of the entity and the other feature occur within some spatial range of each other, or that additional non-name features occur in the document. The disambiguation engine 310 identifies 402 a first set of documents that, based on the first model, are likely to refer to the entity. A feature can be a fact stored in a fact repository, or any word, n-gram, or syntactic or semantic feature of the text.

In one embodiment, determining 404 a subsequent model includes analyzing the available documents and the first set of documents. The disambiguation engine 310 counts the number of occurrences of features in the available documents, the number of occurrences of features in the first set of documents, the total number of available documents, and the number of documents in the first set. The number of documents in the first set and the number of available documents can be used to estimate the probability that a document refers to the entity. The number of occurrences of a particular feature in the available documents and the total number of available documents can be used to estimate the probability of the feature occurring in a document. The number of occurrences of a particular feature in the first set of documents and the number of documents in the first set can be used to estimate the probability of the feature occurring in a document that refers to the entity. The probability that a document refers to the entity, the probability of a feature occurring in a document, and the probability of the feature occurring in a document that refers to the entity can be used to estimate the probability that a document refers to the entity given that a particular feature occurs. In one embodiment, a subsequent model is based on a set of estimated probabilities that a document refers to the entity given that a particular feature occurs.

In one embodiment, identifying 406 documents referring to the entity using the determined 404 model includes determining the probability that a document refers to the entity. The probability that a document refers to the entity can be based on a combination of the probabilities that a document refers to the entity given that a particular feature occurs (as indicated by the model) for all features that occur in the document. In one embodiment, documents with a higher likelihood of referring the entity compared to other available documents are identified 406 as referring to the entity.

In various embodiments, various probabilistic techniques can be implemented to estimate the probability that a document refers to an entity using an iterative series of models. For example, in one embodiment, a Bayes Net Noisy-Or model is used to model the documents and to estimate the probability that documents refer to various entities. Other example of models and probabilistic techniques (including decision trees, maximum entropy models, and so on) will be apparent to one of skill in the art without departing from the scope of the present invention.

FIG. 5 illustrates several examples of features associated with an entity and features associated with various documents, according to one embodiment of the present invention. In the example illustrated, the entity 502 is Michael Jackson, the former member of the Jackson 5, commonly known as the “King of Pop”. The entity 502 is associated with several features 504, including, for example, the name “Michael Jackson”, the birthday “Aug. 29, 1958”, the sobriquet “King of Pop”, membership in “Jackson 5” and citizenship of “USA”. In one embodiment, the features 502 associated with entity 502 are stored as facts in a fact repository.

The Michael Jackson described above is given as an example of an entity 502 for which it is desired to disambiguate references. For example, documents can be collected from the world wide web and analyzed to determine if they refer the entity 502. Examples of such documents are shown as document 508 and document 512, which can be obtained from a variety of potential sources.

Document 508 contains some text describing a “Michael Jackson”. Based on the contents of the document 508, some features 510 are associated with the document 508. In the example illustrated, the features 510 include “Michael Jackson”, “Aug. 29, 1958”, “Jackson 5”, “King of Pop”, “France” and “Canada”.

Document 512 also contains some text describing a “Michael Jackson”. Based on the contents of the document 512, some features 514 are associated with the document 512. In the example illustrated, the features 514 include “Michael Jackson”, “Secretary”, “USA”, “Code Orange” and “King”. It is desired to estimate the probability that document 508 refers to the entity 502, and to estimate the probability that document 512 refers to the entity 502.

In one embodiment, the disambiguation engine 310 identifies 402 documents referring to the entity 502 using a first model. For example, the disambiguation engine 310 identifies documents containing the name of the entity 502 and one other non-name feature. In the example illustrated, using the first model the document 508 is identified 402 as referring to the entity 502, because the document 508 matches some of the features 504, specifically “Michael Jackson”, “Aug. 29, 1958”, and “King of Pop”. In the example illustrated, using the first model the document 512 is also identified 402 as referring to the entity 502, because the document 512 contains the features “Michael Jackson” and “USA”. In one embodiment, additional documents (not shown) are also analyzed. The other documents may or may not contain sufficient features to be identified as referring to the entity 502 using the first model.

Based on the features of the document 508, the document 512, and other documents identified 402 as referring to the entity 502 using the first model, the disambiguation engine 310 determines 404 a subsequent model. For example, analysis of the identified 402 documents may indicate that the feature “Aug. 29, 1958” occurs frequently in the identified 402 documents and less frequently in other available documents. Therefore, in the subsequent model, the feature “Aug. 29, 1958” would be considered more indicative of a reference to the entity 502 than other features. As another example, analysis of the identified 402 documents may indicate that the feature “USA” occurs sometimes in the identified 402 documents, but with similar frequency in the available documents as a whole. Therefore, in the subsequent model, the feature “USA” would not be considered more indicative of a reference to the entity 502 than other features, and in fact might be considered less indicative of a reference to the entity 502 than other features.

The disambiguation engine 310 identifies 406 documents referring to the entity 502 using the determined 404 model. In the new model, the feature “Aug. 29, 1958” is given more weight than the feature “USA”. Using the new model, document 508 is identified 406 as referring to the entity 502, because the document 508 contains several features considered highly indicative of references to the entity 502. On the other hand, using the new model, document 512 is not identified 406 as referring to the entity 502, because the document 508 contains only a few features, and those features are not considered highly indicative of references to the entity 502. Advantageously, documents not referring to the entity 502 are not included in the set of documents referring to the entity, despite being included in the set of documents identified using the first model.

Furthermore, additional documents (not shown) that were not identified 402 as referring to the entity 502 using the first model can be identified 406 as referring to the entity 406 using the subsequent model. Such documents may contain features not considered indicative of reference to the entity under the first (or previous) model, but that are considered indicative of reference to the entity under the subsequent model. Advantageously, documents referring to the entity 502 are included in the set of documents referring to the entity, despite not being included in the set of documents identified using the first model.

In one embodiment, a feature of the entity and a feature in a document need not match exactly for the feature of the entity to be considered to be present in the document. Various techniques such as string clustering, proximity estimation, and so on can be used to determine if a feature is contained in a document. For example, a document containing the text “Michel Jackson” might be determined to contain the feature “Michael Jackson”, despite differences in the literal text. Features can be matched based on acoustic similarity, keyword proximity, synonymy, membership in the same category in a semantic network and so on. In one embodiment, features can be matched based on edit distance models that account for typographical errors attributed to keyboard layout. For example, the feature “magazine” might be matched by the text “magazune” because of the proximity in keyboard layout of the letter ‘i’ and the letter ‘u’. Canonicalization and other information organizing techniques can also be applied to features in the document to facilitate comparison to the features of the entity. For example, in the example illustrated in FIG. 5, document 508 includes the text “Aug. 29, 1958”. This date can be canonicalized as “8/29/1958” for efficient comparison to features of the entity.

In one embodiment, the domain from which a document is obtained can be considered a feature of the document, or can imply other features in the document. For example, a document retrieved from “espn.com” could implicitly match the features “sports” and “espn” even if neither of the words is actually present. Similarly, a page on the UCLA domain could implicitly match the features “ucla” and “university of california”. Basing matches on the source from which a document was obtained advantageously improves disambiguation of references.

In one embodiment, a feature of an entity can be recognized in a document based on category. For example, the entity “Bud Selig” may be associated with the feature “baseball team”. The feature “baseball team” can be identified as a category including one or more members. A document containing the feature “white sox” (an example of a member of the “baseball team” category) would be recognized as containing the feature “baseball team”, even though the term “baseball team” might not literally appear in the document. Features identified by category can be weighted, for example, by the estimated likelihood that the feature is a true member of the category.

Reference in the specification to “one embodiment” or to “an embodiment” means that a particular feature, structure, or characteristic described in connection with the embodiments is included in at least one embodiment of the invention. The appearances of the phrase “in one embodiment” in various places in the specification are not necessarily all referring to the same embodiment.

Some portions of the above are presented in terms of algorithms and symbolic representations of operations on data bits within a computer memory. These algorithmic descriptions and representations are the means used by those skilled in the data processing arts to most effectively convey the substance of their work to others skilled in the art. An algorithm is here, and generally, conceived to be a self-consistent sequence of steps (instructions) leading to a desired result. The steps are those requiring physical manipulations of physical quantities. Usually, though not necessarily, these quantities take the form of electrical, magnetic or optical signals capable of being stored, transferred, combined, compared and otherwise manipulated. It is convenient at times, principally for reasons of common usage, to refer to these signals as bits, values, elements, symbols, characters, terms, numbers, or the like. Furthermore, it is also convenient at times, to refer to certain arrangements of steps requiring physical manipulations of physical quantities as modules or code devices, without loss of generality.

It should be borne in mind, however, that all of these and similar terms are to be associated with the appropriate physical quantities and are merely convenient labels applied to these quantities. Unless specifically stated otherwise as apparent from the following discussion, it is appreciated that throughout the description, discussions utilizing terms such as “processing” or “computing” or “calculating” or “determining” or “displaying” or “determining” or the like, refer to the action and processes of a computer system, or similar electronic computing device, that manipulates and transforms data represented as physical (electronic) quantities within the computer system memories or registers or other such information storage, transmission or display devices.

Certain aspects of the present invention include process steps and instructions described herein in the form of an algorithm. It should be noted that the process steps and instructions of the present invention can be embodied in software, firmware or hardware, and when embodied in software, can be downloaded to reside on and be operated from different platforms used by a variety of operating systems.

The present invention also relates to an apparatus for performing the operations herein. This apparatus may be specially constructed for the required purposes, or it may comprise a general-purpose computer selectively activated or reconfigured by a computer program stored in the computer. Such a computer program may be stored in a computer readable storage medium, such as, but is not limited to, any type of disk including floppy disks, optical disks, CD-ROMs, magnetic-optical disks, read-only memories (ROMs), random access memories (RAMs), EPROMs, EEPROMs, magnetic or optical cards, application specific integrated circuits (ASICs), or any type of media suitable for storing electronic instructions, and each coupled to a computer system bus. Furthermore, the computers referred to in the specification may include a single processor or may be architectures employing multiple processor designs for increased computing capability.

The algorithms and displays presented herein are not inherently related to any particular computer or other apparatus. Various general-purpose systems may also be used with programs in accordance with the teachings herein, or it may prove convenient to construct more specialized apparatus to perform the required method steps. The required structure for a variety of these systems will appear from the description below. In addition, the present invention is not described with reference to any particular programming language. It will be appreciated that a variety of programming languages may be used to implement the teachings of the present invention as described herein, and any references below to specific languages are provided for disclosure of enablement and best mode of the present invention.

While the invention has been particularly shown and described with reference to an embodiment and several alternate embodiments, it will be understood by persons skilled in the relevant art that various changes in form and details can be made therein without departing from the spirit and scope of the invention.

Finally, it should be noted that the language used in the specification has been principally selected for readability and instructional purposes, and may not have been selected to delineate or circumscribe the inventive subject matter. Accordingly, the disclosure of the present invention is intended to be illustrative, but not limiting, of the scope of the invention, which is set forth in the following claims. 

1. A method for identifying documents referring to an entity, the entity being associated with a first set of features, the method comprising: identifying a first set of documents based on a first model and the first set of features, the first set of documents each comprising a sufficient number of features in common with the first set of features to identify a document referring to the entity according to the first model; determining a second model based on the features of the first set of documents; and identifying a second set of documents based on the second model and the first set of features, the second set of documents each comprising a sufficient number of features in common with the first set of features to identify a document referring to the entity according to the second model. 